From 9043add656177eeac1491a73d2f3ab92bec0013c Mon Sep 17 00:00:00 2001 From: Benjamin Barenblat Date: Sat, 29 Dec 2018 14:31:27 -0500 Subject: Imported Upstream version 8.8.2 --- pretyping/reductionops.ml | 757 +++++++++++++++++++++++++--------------------- 1 file changed, 418 insertions(+), 339 deletions(-) (limited to 'pretyping/reductionops.ml') diff --git a/pretyping/reductionops.ml b/pretyping/reductionops.ml index 297f0a1a..360c6e86 100644 --- a/pretyping/reductionops.ml +++ b/pretyping/reductionops.ml @@ -1,20 +1,23 @@ (************************************************************************) -(* v * The Coq Proof Assistant / The Coq Development Team *) -(* !refolding_in_reduction); - Goptions.optwrite = (fun a -> refolding_in_reduction:=a); + "Generate weak constraints between Irrelevant universes"; + Goptions.optkey = ["Cumulativity";"Weak";"Constraints"]; + Goptions.optread = (fun () -> not !UState.drop_weak_constraints); + Goptions.optwrite = (fun a -> UState.drop_weak_constraints:=not a); } -let get_refolding_in_reduction () = !refolding_in_reduction -let set_refolding_in_reduction = (:=) refolding_in_reduction + +(** Support for reduction effects *) + +open Mod_subst +open Libobject + +type effect_name = string + +(** create a persistent set to store effect functions *) +module ConstrMap = Map.Make (Constr) + +(* Table bindings a constant to an effect *) +let constant_effect_table = Summary.ref ~name:"reduction-side-effect" ConstrMap.empty + +(* Table bindings function key to effective functions *) +let effect_table = Summary.ref ~name:"reduction-function-effect" String.Map.empty + +(** a test to know whether a constant is actually the effect function *) +let reduction_effect_hook env sigma termkey c = + try + let funkey = ConstrMap.find termkey !constant_effect_table in + let effect = String.Map.find funkey !effect_table in + effect env sigma (Lazy.force c) + with Not_found -> () + +let cache_reduction_effect (_,(termkey,funkey)) = + constant_effect_table := ConstrMap.add termkey funkey !constant_effect_table + +let subst_reduction_effect (subst,(termkey,funkey)) = + (subst_mps subst termkey,funkey) + +let inReductionEffect : Constr.constr * string -> obj = + declare_object {(default_object "REDUCTION-EFFECT") with + cache_function = cache_reduction_effect; + open_function = (fun i o -> if Int.equal i 1 then cache_reduction_effect o); + subst_function = subst_reduction_effect; + classify_function = (fun o -> Substitute o) } + +let declare_reduction_effect funkey f = + if String.Map.mem funkey !effect_table then + CErrors.anomaly Pp.(str "Cannot redeclare effect function " ++ qstring funkey ++ str "."); + effect_table := String.Map.add funkey f !effect_table + +(** A function to set the value of the print function *) +let set_reduction_effect x funkey = + let termkey = Universes.constr_of_global x in + Lib.add_anonymous_leaf (inReductionEffect (termkey,funkey)) + (** Machinery to custom the behavior of the reduction *) module ReductionBehaviour = struct @@ -72,10 +120,10 @@ module ReductionBehaviour = struct let r' = fst (subst_global subst r) in if r==r' then orig else (r',o) let discharge = function - | _,(ReqGlobal (ConstRef c, req), (_, b)) -> + | _,(ReqGlobal (ConstRef c as gr, req), (_, b)) -> let b = - if Lib.is_in_section (ConstRef c) then - let vars, _, _ = Lib.section_segment_of_constant c in + if Lib.is_in_section gr then + let vars = Lib.variable_section_segment_of_reference gr in let extra = List.length vars in let nargs' = if b.b_nargs = max_int then max_int @@ -156,6 +204,7 @@ end (** Machinery about stack of unfolded constants *) module Cst_stack = struct + open EConstr (** constant * params * args - constant applied to params = term in head applied to args @@ -191,24 +240,24 @@ module Cst_stack = struct | (cst,params,[])::_ -> Some(cst,params) | _ -> None - let reference t = match best_cst t with - | Some (c, _) when Term.isConst c -> Some (fst (Term.destConst c)) + let reference sigma t = match best_cst t with + | Some (c, _) when isConst sigma c -> Some (fst (destConst sigma c)) | _ -> None (** [best_replace d cst_l c] makes the best replacement for [d] by [cst_l] in [c] *) - let best_replace d cst_l c = + let best_replace sigma d cst_l c = let reconstruct_head = List.fold_left (fun t (i,args) -> mkApp (t,Array.sub args i (Array.length args - i))) in List.fold_right - (fun (cst,params,args) t -> Termops.replace_term + (fun (cst,params,args) t -> Termops.replace_term sigma (reconstruct_head d args) (applist (cst, List.rev params)) t) cst_l c let pr l = let open Pp in - let p_c = Termops.print_constr in + let p_c c = Termops.print_constr c in prlist_with_sep pr_semicolon (fun (c,params,args) -> hov 1 (str"(" ++ p_c c ++ str ")" ++ spc () ++ pr_sequence p_c params ++ spc () ++ str "(args:" ++ @@ -220,34 +269,36 @@ end (** The type of (machine) stacks (= lambda-bar-calculus' contexts) *) module Stack : sig + open EConstr type 'a app_node - val pr_app_node : ('a -> Pp.std_ppcmds) -> 'a app_node -> Pp.std_ppcmds + val pr_app_node : ('a -> Pp.t) -> 'a app_node -> Pp.t type cst_member = | Cst_const of pconstant - | Cst_proj of projection + | Cst_proj of Projection.t type 'a member = | App of 'a app_node | Case of case_info * 'a * 'a array * Cst_stack.t - | Proj of int * int * projection * Cst_stack.t - | Fix of fixpoint * 'a t * Cst_stack.t + | Proj of int * int * Projection.t * Cst_stack.t + | Fix of ('a, 'a) pfixpoint * 'a t * Cst_stack.t | Cst of cst_member * int * int list * 'a t * Cst_stack.t - | Shift of int - | Update of 'a and 'a t = 'a member list - val pr : ('a -> Pp.std_ppcmds) -> 'a t -> Pp.std_ppcmds + + exception IncompatibleFold2 + + val pr : ('a -> Pp.t) -> 'a t -> Pp.t val empty : 'a t val is_empty : 'a t -> bool val append_app : 'a array -> 'a t -> 'a t val decomp : 'a t -> ('a * 'a t) option val decomp_node_last : 'a app_node -> 'a t -> ('a * 'a t) - val equal : ('a * int -> 'a * int -> bool) -> (fixpoint * int -> fixpoint * int -> bool) - -> 'a t -> 'a t -> (int * int) option + val equal : ('a -> 'a -> bool) -> (('a, 'a) pfixpoint -> ('a, 'a) pfixpoint -> bool) + -> 'a t -> 'a t -> bool val compare_shape : 'a t -> 'a t -> bool - val map : (constr -> constr) -> constr t -> constr t + val map : ('a -> 'a) -> 'a t -> 'a t val fold2 : ('a -> constr -> constr -> 'a) -> 'a -> - constr t -> constr t -> 'a * int * int + constr t -> constr t -> 'a val append_app_list : 'a list -> 'a t -> 'a t val strip_app : 'a t -> 'a t * 'a t val strip_n_app : int -> 'a t -> ('a t * 'a * 'a t) option @@ -258,10 +309,11 @@ sig val args_size : 'a t -> int val tail : int -> 'a t -> 'a t val nth : 'a t -> int -> 'a - val best_state : constr * constr t -> Cst_stack.t -> constr * constr t - val zip : ?refold:bool -> constr * constr t -> constr + val best_state : evar_map -> constr * constr t -> Cst_stack.t -> constr * constr t + val zip : ?refold:bool -> evar_map -> constr * constr t -> constr end = struct + open EConstr type 'a app_node = int * 'a array * int (* first releavnt position, arguments, last relevant position *) @@ -280,16 +332,14 @@ struct type cst_member = | Cst_const of pconstant - | Cst_proj of projection + | Cst_proj of Projection.t type 'a member = | App of 'a app_node - | Case of Term.case_info * 'a * 'a array * Cst_stack.t - | Proj of int * int * projection * Cst_stack.t - | Fix of fixpoint * 'a t * Cst_stack.t + | Case of case_info * 'a * 'a array * Cst_stack.t + | Proj of int * int * Projection.t * Cst_stack.t + | Fix of ('a, 'a) pfixpoint * 'a t * Cst_stack.t | Cst of cst_member * int * int list * 'a t * Cst_stack.t - | Shift of int - | Update of 'a and 'a t = 'a member list let rec pr_member pr_c member = @@ -303,17 +353,15 @@ struct ++ str ")" | Proj (n,m,p,cst) -> str "ZProj(" ++ int n ++ pr_comma () ++ int m ++ - pr_comma () ++ pr_con (Projection.constant p) ++ str ")" + pr_comma () ++ Constant.print (Projection.constant p) ++ str ")" | Fix (f,args,cst) -> - str "ZFix(" ++ Termops.pr_fix Termops.print_constr f + str "ZFix(" ++ Termops.pr_fix pr_c f ++ pr_comma () ++ pr pr_c args ++ str ")" | Cst (mem,curr,remains,params,cst_l) -> str "ZCst(" ++ pr_cst_member pr_c mem ++ pr_comma () ++ int curr ++ pr_comma () ++ prlist_with_sep pr_semicolon int remains ++ pr_comma () ++ pr pr_c params ++ str ")" - | Shift i -> str "ZShift(" ++ int i ++ str ")" - | Update t -> str "ZUpdate(" ++ pr_c t ++ str ")" and pr pr_c l = let open Pp in prlist_with_sep pr_semicolon (fun x -> hov 1 (pr_member pr_c x)) l @@ -348,54 +396,42 @@ struct else (l.(j), sk) let equal f f_fix sk1 sk2 = - let equal_cst_member x lft1 y lft2 = + let equal_cst_member x y = match x, y with | Cst_const (c1,u1), Cst_const (c2, u2) -> - Constant.equal c1 c2 && Univ.Instance.equal u1 u2 + Constant.equal c1 c2 && Univ.Instance.equal u1 u2 | Cst_proj p1, Cst_proj p2 -> - Constant.equal (Projection.constant p1) (Projection.constant p2) + Constant.equal (Projection.constant p1) (Projection.constant p2) | _, _ -> false in - let rec equal_rec sk1 lft1 sk2 lft2 = + let rec equal_rec sk1 sk2 = match sk1,sk2 with - | [],[] -> Some (lft1,lft2) - | (Update _ :: _, _ | _, Update _ :: _) -> assert false - | Shift k :: s1, _ -> equal_rec s1 (lft1+k) sk2 lft2 - | _, Shift k :: s2 -> equal_rec sk1 lft1 s2 (lft2+k) + | [],[] -> true | App a1 :: s1, App a2 :: s2 -> - let t1,s1' = decomp_node_last a1 s1 in - let t2,s2' = decomp_node_last a2 s2 in - if f (t1,lft1) (t2,lft2) then equal_rec s1' lft1 s2' lft2 else None + let t1,s1' = decomp_node_last a1 s1 in + let t2,s2' = decomp_node_last a2 s2 in + (f t1 t2) && (equal_rec s1' s2') | Case (_,t1,a1,_) :: s1, Case (_,t2,a2,_) :: s2 -> - if f (t1,lft1) (t2,lft2) && CArray.equal (fun x y -> f (x,lft1) (y,lft2)) a1 a2 - then equal_rec s1 lft1 s2 lft2 - else None + f t1 t2 && CArray.equal (fun x y -> f x y) a1 a2 && equal_rec s1 s2 | (Proj (n1,m1,p,_)::s1, Proj(n2,m2,p2,_)::s2) -> - if Int.equal n1 n2 && Int.equal m1 m2 - && Constant.equal (Projection.constant p) (Projection.constant p2) - then equal_rec s1 lft1 s2 lft2 - else None + Int.equal n1 n2 && Int.equal m1 m2 + && Constant.equal (Projection.constant p) (Projection.constant p2) + && equal_rec s1 s2 | Fix (f1,s1,_) :: s1', Fix (f2,s2,_) :: s2' -> - if f_fix (f1,lft1) (f2,lft2) then - match equal_rec (List.rev s1) lft1 (List.rev s2) lft2 with - | None -> None - | Some (lft1',lft2') -> equal_rec s1' lft1' s2' lft2' - else None + f_fix f1 f2 + && equal_rec (List.rev s1) (List.rev s2) + && equal_rec s1' s2' | Cst (c1,curr1,remains1,params1,_)::s1', Cst (c2,curr2,remains2,params2,_)::s2' -> - if equal_cst_member c1 lft1 c2 lft2 then - match equal_rec (List.rev params1) lft1 (List.rev params2) lft2 with - | Some (lft1',lft2') -> equal_rec s1' lft1' s2' lft2' - | None -> None - else None - | ((App _|Case _|Proj _|Fix _|Cst _)::_|[]), _ -> None - in equal_rec (List.rev sk1) 0 (List.rev sk2) 0 + equal_cst_member c1 c2 + && equal_rec (List.rev params1) (List.rev params2) + && equal_rec s1' s2' + | ((App _|Case _|Proj _|Fix _|Cst _)::_|[]), _ -> false + in equal_rec (List.rev sk1) (List.rev sk2) let compare_shape stk1 stk2 = let rec compare_rec bal stk1 stk2 = match (stk1,stk2) with ([],[]) -> Int.equal bal 0 - | ((Update _|Shift _)::s1, _) -> compare_rec bal s1 stk2 - | (_, (Update _|Shift _)::s2) -> compare_rec bal stk1 s2 | (App (i,_,j)::s1, _) -> compare_rec (bal + j + 1 - i) s1 stk2 | (_, App (i,_,j)::s2) -> compare_rec (bal - j - 1 + i) stk1 s2 | (Case(c1,_,_,_)::s1, Case(c2,_,_,_)::s2) -> @@ -409,41 +445,31 @@ struct | (_,_) -> false in compare_rec 0 stk1 stk2 + exception IncompatibleFold2 let fold2 f o sk1 sk2 = - let rec aux o lft1 sk1 lft2 sk2 = - let fold_array = - Array.fold_left2 (fun a x y -> f a (Vars.lift lft1 x) (Vars.lift lft2 y)) - in + let rec aux o sk1 sk2 = match sk1,sk2 with - | [], [] -> o,lft1,lft2 - | Shift n :: q1, _ -> aux o (lft1+n) q1 lft2 sk2 - | _, Shift n :: q2 -> aux o lft1 sk1 (lft2+n) q2 + | [], [] -> o | App n1 :: q1, App n2 :: q2 -> - let t1,l1 = decomp_node_last n1 q1 in - let t2,l2 = decomp_node_last n2 q2 in - aux (f o (Vars.lift lft1 t1) (Vars.lift lft2 t2)) - lft1 l1 lft2 l2 + let t1,l1 = decomp_node_last n1 q1 in + let t2,l2 = decomp_node_last n2 q2 in + aux (f o t1 t2) l1 l2 | Case (_,t1,a1,_) :: q1, Case (_,t2,a2,_) :: q2 -> - aux (fold_array - (f o (Vars.lift lft1 t1) (Vars.lift lft2 t2)) - a1 a2) lft1 q1 lft2 q2 + aux (Array.fold_left2 f (f o t1 t2) a1 a2) q1 q2 | Proj (n1,m1,p1,_) :: q1, Proj (n2,m2,p2,_) :: q2 -> - aux o lft1 q1 lft2 q2 + aux o q1 q2 | Fix ((_,(_,a1,b1)),s1,_) :: q1, Fix ((_,(_,a2,b2)),s2,_) :: q2 -> - let (o',lft1',lft2') = aux (fold_array (fold_array o b1 b2) a1 a2) - lft1 (List.rev s1) lft2 (List.rev s2) in - aux o' lft1' q1 lft2' q2 + let o' = aux (Array.fold_left2 f (Array.fold_left2 f o b1 b2) a1 a2) (List.rev s1) (List.rev s2) in + aux o' q1 q2 | Cst (cst1,_,_,params1,_) :: q1, Cst (cst2,_,_,params2,_) :: q2 -> - let (o',lft1',lft2') = - aux o lft1 (List.rev params1) lft2 (List.rev params2) - in aux o' lft1' q1 lft2' q2 - | (((Update _|App _|Case _|Proj _|Fix _| Cst _) :: _|[]), _) -> - raise (Invalid_argument "Reductionops.Stack.fold2") - in aux o 0 (List.rev sk1) 0 (List.rev sk2) + let o' = aux o (List.rev params1) (List.rev params2) in + aux o' q1 q2 + | (((App _|Case _|Proj _|Fix _| Cst _) :: _|[]), _) -> + raise IncompatibleFold2 + in aux o (List.rev sk1) (List.rev sk2) let rec map f x = List.map (function - | Update _ -> assert false - | (Proj (_,_,_,_) | Shift _) as e -> e + | (Proj (_,_,_,_)) as e -> e | App (i,a,j) -> let le = j - i + 1 in App (0,Array.map f (Array.sub a i le), le-1) @@ -460,18 +486,15 @@ struct let rec args_size = function | App (i,_,j)::s -> j + 1 - i + args_size s - | Shift(_)::s -> args_size s - | Update(_)::s -> args_size s | (Case _|Fix _|Proj _|Cst _)::_ | [] -> 0 let strip_app s = let rec aux out = function - | ( App _ | Shift _ as e) :: s -> aux (e :: out) s + | ( App _ as e) :: s -> aux (e :: out) s | s -> List.rev out,s in aux [] s let strip_n_app n s = let rec aux n out = function - | Shift k as e :: s -> aux n (e :: out) s | App (i,a,j) as e :: s -> let nb = j - i + 1 in if n >= nb then @@ -496,14 +519,12 @@ struct let list_of_app_stack s = let rec aux = function | App (i,a,j) :: s -> - let (k,(args',s')) = aux s in - let a' = Array.map (Vars.lift k) (Array.sub a i (j - i + 1)) in - k,(Array.fold_right (fun x y -> x::y) a' args', s') - | Shift n :: s -> - let (k,(args',s')) = aux s in (k+n,(args', s')) - | s -> (0,([],s)) in - let (lft,(out,s')) = aux s in - let init = match s' with [] when Int.equal lft 0 -> true | _ -> false in + let (args',s') = aux s in + let a' = Array.sub a i (j - i + 1) in + (Array.fold_right (fun x y -> x::y) a' args', s') + | s -> ([],s) in + let (out,s') = aux s in + let init = match s' with [] -> true | _ -> false in Option.init init out let assign s p c = @@ -512,20 +533,18 @@ struct | None -> assert false let tail n0 s0 = - let rec aux lft n s = - let out s = if Int.equal lft 0 then s else Shift lft :: s in - if Int.equal n 0 then out s else + let rec aux n s = + if Int.equal n 0 then s else match s with | App (i,a,j) :: s -> let nb = j - i + 1 in if n >= nb then - aux lft (n - nb) s + aux (n - nb) s else let p = i+n in if j >= p then App(p,a,j)::s else s - | Shift k :: s' -> aux (lft+k) n s' | _ -> raise (Invalid_argument "Reductionops.Stack.tail") - in aux 0 n0 s0 + in aux n0 s0 let nth s p = match strip_n_app p s with @@ -533,11 +552,11 @@ struct | None -> raise Not_found (** This function breaks the abstraction of Cst_stack ! *) - let best_state (_,sk as s) l = + let best_state sigma (_,sk as s) l = let rec aux sk def = function |(cst, params, []) -> (cst, append_app_list (List.rev params) sk) |(cst, params, (i,t)::q) -> match decomp sk with - | Some (el,sk') when Constr.equal el t.(i) -> + | Some (el,sk') when EConstr.eq_constr sigma el t.(i) -> if i = pred (Array.length t) then aux sk' def (cst, params, q) else aux sk' def (cst, params, (succ i,t)::q) @@ -546,59 +565,62 @@ struct let constr_of_cst_member f sk = match f with - | Cst_const (c, u) -> mkConstU (c,u), sk + | Cst_const (c, u) -> mkConstU (c, EInstance.make u), sk | Cst_proj p -> match decomp sk with | Some (hd, sk) -> mkProj (p, hd), sk | None -> assert false - let rec zip ?(refold=false) = function + let zip ?(refold=false) sigma s = + let rec zip = function | f, [] -> f | f, (App (i,a,j) :: s) -> let a' = if Int.equal i 0 && Int.equal j (Array.length a - 1) then a else Array.sub a i (j - i + 1) in - zip ~refold (mkApp (f, a'), s) + zip (mkApp (f, a'), s) | f, (Case (ci,rt,br,cst_l)::s) when refold -> - zip ~refold (best_state (mkCase (ci,rt,f,br), s) cst_l) - | f, (Case (ci,rt,br,_)::s) -> zip ~refold (mkCase (ci,rt,f,br), s) + zip (best_state sigma (mkCase (ci,rt,f,br), s) cst_l) + | f, (Case (ci,rt,br,_)::s) -> zip (mkCase (ci,rt,f,br), s) | f, (Fix (fix,st,cst_l)::s) when refold -> - zip ~refold (best_state (mkFix fix, st @ (append_app [|f|] s)) cst_l) - | f, (Fix (fix,st,_)::s) -> zip ~refold + zip (best_state sigma (mkFix fix, st @ (append_app [|f|] s)) cst_l) + | f, (Fix (fix,st,_)::s) -> zip (mkFix fix, st @ (append_app [|f|] s)) | f, (Cst (cst,_,_,params,cst_l)::s) when refold -> - zip ~refold (best_state (constr_of_cst_member cst (params @ (append_app [|f|] s))) cst_l) + zip (best_state sigma (constr_of_cst_member cst (params @ (append_app [|f|] s))) cst_l) | f, (Cst (cst,_,_,params,_)::s) -> - zip ~refold (constr_of_cst_member cst (params @ (append_app [|f|] s))) - | f, (Shift n::s) -> zip ~refold (lift n f, s) + zip (constr_of_cst_member cst (params @ (append_app [|f|] s))) | f, (Proj (n,m,p,cst_l)::s) when refold -> - zip ~refold (best_state (mkProj (p,f),s) cst_l) - | f, (Proj (n,m,p,_)::s) -> zip ~refold (mkProj (p,f),s) - | _, (Update _::_) -> assert false + zip (best_state sigma (mkProj (p,f),s) cst_l) + | f, (Proj (n,m,p,_)::s) -> zip (mkProj (p,f),s) + in + zip s + end (** The type of (machine) states (= lambda-bar-calculus' cuts) *) type state = constr * constr Stack.t -type contextual_reduction_function = env -> evar_map -> constr -> constr -type reduction_function = contextual_reduction_function +type contextual_reduction_function = env -> evar_map -> constr -> constr +type reduction_function = contextual_reduction_function type local_reduction_function = evar_map -> constr -> constr -type e_reduction_function = { e_redfun : 'r. env -> 'r Sigma.t -> constr -> (constr, 'r) Sigma.sigma } +type e_reduction_function = env -> evar_map -> constr -> evar_map * constr -type contextual_stack_reduction_function = - env -> evar_map -> constr -> constr * constr list -type stack_reduction_function = contextual_stack_reduction_function +type contextual_stack_reduction_function = + env -> evar_map -> constr -> constr * constr list +type stack_reduction_function = contextual_stack_reduction_function type local_stack_reduction_function = evar_map -> constr -> constr * constr list -type contextual_state_reduction_function = - env -> evar_map -> state -> state -type state_reduction_function = contextual_state_reduction_function +type contextual_state_reduction_function = + env -> evar_map -> state -> state +type state_reduction_function = contextual_state_reduction_function type local_state_reduction_function = evar_map -> state -> state let pr_state (tm,sk) = let open Pp in - h 0 (Termops.print_constr tm ++ str "|" ++ cut () ++ Stack.pr Termops.print_constr sk) + let pr c = Termops.print_constr c in + h 0 (pr tm ++ str "|" ++ cut () ++ Stack.pr pr sk) (*************************************) (*** Reduction Functions Operators ***) @@ -612,16 +634,16 @@ let safe_meta_value sigma ev = let strong whdfun env sigma t = let rec strongrec env t = - map_constr_with_full_binders push_rel strongrec env (whdfun env sigma t) in + map_constr_with_full_binders sigma push_rel strongrec env (whdfun env sigma t) in strongrec env t let local_strong whdfun sigma = - let rec strongrec t = Constr.map strongrec (whdfun sigma t) in + let rec strongrec t = EConstr.map sigma strongrec (whdfun sigma t) in strongrec let rec strong_prodspine redfun sigma c = let x = redfun sigma c in - match kind_of_term x with + match EConstr.kind sigma x with | Prod (na,a,b) -> mkProd (na,a,strong_prodspine redfun sigma b) | _ -> x @@ -633,20 +655,25 @@ let eta = CClosure.RedFlags.mkflags [CClosure.RedFlags.fETA] (* Beta Reduction tools *) -let apply_subst recfun env refold cst_l t stack = +let apply_subst recfun env sigma refold cst_l t stack = let rec aux env cst_l t stack = - match (Stack.decomp stack,kind_of_term t) with + match (Stack.decomp stack, EConstr.kind sigma t) with | Some (h,stacktl), Lambda (_,_,c) -> let cst_l' = if refold then Cst_stack.add_param h cst_l else cst_l in aux (h::env) cst_l' c stacktl - | _ -> recfun cst_l (substl env t, stack) + | _ -> recfun sigma cst_l (substl env t, stack) in aux env cst_l t stack -let stacklam recfun env t stack = - apply_subst (fun _ -> recfun) env false Cst_stack.empty t stack +let stacklam recfun env sigma t stack = + apply_subst (fun _ _ s -> recfun s) env sigma false Cst_stack.empty t stack + +let beta_app sigma (c,l) = + let zip s = Stack.zip sigma s in + stacklam zip [] sigma c (Stack.append_app l Stack.empty) -let beta_applist (c,l) = - stacklam Stack.zip [] c (Stack.append_app_list l Stack.empty) +let beta_applist sigma (c,l) = + let zip s = Stack.zip sigma s in + stacklam zip [] sigma c (Stack.append_app_list l Stack.empty) (* Iota reduction tools *) @@ -657,7 +684,7 @@ type 'a miota_args = { mcargs : 'a list; (* the constructor's arguments *) mlf : 'a array } (* the branch code vector *) -let reducible_mind_case c = match kind_of_term c with +let reducible_mind_case sigma c = match EConstr.kind sigma c with | Construct _ | CoFix _ -> true | _ -> false @@ -671,27 +698,38 @@ let reducible_mind_case c = match kind_of_term c with f x := t. End M. Definition f := u. and say goodbye to any hope of refolding M.f this way ... *) -let magicaly_constant_of_fixbody env reference bd = function +let magicaly_constant_of_fixbody env sigma reference bd = function | Name.Anonymous -> bd | Name.Name id -> + let open Universes in try let (cst_mod,cst_sect,_) = Constant.repr3 reference in let cst = Constant.make3 cst_mod cst_sect (Label.of_id id) in - let (cst, u), ctx = Universes.fresh_constant_instance env cst in + let (cst, u), ctx = fresh_constant_instance env cst in match constant_opt_value_in env (cst,u) with | None -> bd | Some t -> - let b, csts = Universes.eq_constr_universes t bd in - let subst = Universes.Constraints.fold (fun (l,d,r) acc -> - Univ.LMap.add (Option.get (Universe.level l)) (Option.get (Universe.level r)) acc) - csts Univ.LMap.empty - in - let inst = Instance.subst_fn (fun u -> Univ.LMap.find u subst) u in - if b then mkConstU (cst,inst) else bd + let csts = EConstr.eq_constr_universes env sigma (EConstr.of_constr t) bd in + begin match csts with + | Some csts -> + let subst = Constraints.fold (fun cst acc -> + let l, r = match cst with + | ULub (u, v) | UWeak (u, v) -> u, v + | UEq (u, v) | ULe (u, v) -> + let get u = Option.get (Universe.level u) in + get u, get v + in + Univ.LMap.add l r acc) + csts Univ.LMap.empty + in + let inst = Instance.subst_fn (fun u -> Univ.LMap.find u subst) u in + mkConstU (cst, EInstance.make inst) + | None -> bd + end with | Not_found -> bd -let contract_cofix ?env ?reference (bodynum,(names,types,bodies as typedbodies)) = +let contract_cofix ?env sigma ?reference (bodynum,(names,types,bodies as typedbodies)) = let nbodies = Array.length bodies in let make_Fi j = let ind = nbodies-j-1 in @@ -703,37 +741,37 @@ let contract_cofix ?env ?reference (bodynum,(names,types,bodies as typedbodies)) | Some e -> match reference with | None -> bd - | Some r -> magicaly_constant_of_fixbody e r bd names.(ind) in + | Some r -> magicaly_constant_of_fixbody e sigma r bd names.(ind) in let closure = List.init nbodies make_Fi in substl closure bodies.(bodynum) (** Similar to the "fix" case below *) -let reduce_and_refold_cofix recfun env refold cst_l cofix sk = +let reduce_and_refold_cofix recfun env sigma refold cst_l cofix sk = let raw_answer = let env = if refold then Some env else None in - contract_cofix ?env ?reference:(Cst_stack.reference cst_l) cofix in + contract_cofix ?env sigma ?reference:(Cst_stack.reference sigma cst_l) cofix in apply_subst - (fun x (t,sk') -> + (fun sigma x (t,sk') -> let t' = - if refold then Cst_stack.best_replace (mkCoFix cofix) cst_l t else t in + if refold then Cst_stack.best_replace sigma (mkCoFix cofix) cst_l t else t in recfun x (t',sk')) - [] refold Cst_stack.empty raw_answer sk + [] sigma refold Cst_stack.empty raw_answer sk -let reduce_mind_case mia = - match kind_of_term mia.mconstr with +let reduce_mind_case sigma mia = + match EConstr.kind sigma mia.mconstr with | Construct ((ind_sp,i),u) -> (* let ncargs = (fst mia.mci).(i-1) in*) let real_cargs = List.skipn mia.mci.ci_npar mia.mcargs in applist (mia.mlf.(i-1),real_cargs) | CoFix cofix -> - let cofix_def = contract_cofix cofix in + let cofix_def = contract_cofix sigma cofix in mkCase (mia.mci, mia.mP, applist(cofix_def,mia.mcargs), mia.mlf) | _ -> assert false (* contracts fix==FIX[nl;i](A1...Ak;[F1...Fk]{B1....Bk}) to produce Bi[Fj --> FIX[nl;j](A1...Ak;[F1...Fk]{B1...Bk})] *) -let contract_fix ?env ?reference ((recindices,bodynum),(names,types,bodies as typedbodies)) = +let contract_fix ?env sigma ?reference ((recindices,bodynum),(names,types,bodies as typedbodies)) = let nbodies = Array.length recindices in let make_Fi j = let ind = nbodies-j-1 in @@ -745,7 +783,7 @@ let contract_fix ?env ?reference ((recindices,bodynum),(names,types,bodies as ty | Some e -> match reference with | None -> bd - | Some r -> magicaly_constant_of_fixbody e r bd names.(ind) in + | Some r -> magicaly_constant_of_fixbody e sigma r bd names.(ind) in let closure = List.init nbodies make_Fi in substl closure bodies.(bodynum) @@ -753,18 +791,18 @@ let contract_fix ?env ?reference ((recindices,bodynum),(names,types,bodies as ty replace the fixpoint by the best constant from [cst_l] Other rels are directly substituted by constants "magically found from the context" in contract_fix *) -let reduce_and_refold_fix recfun env refold cst_l fix sk = +let reduce_and_refold_fix recfun env sigma refold cst_l fix sk = let raw_answer = - let env = if refold then None else Some env in - contract_fix ?env ?reference:(Cst_stack.reference cst_l) fix in + let env = if refold then Some env else None in + contract_fix ?env sigma ?reference:(Cst_stack.reference sigma cst_l) fix in apply_subst - (fun x (t,sk') -> + (fun sigma x (t,sk') -> let t' = if refold then - Cst_stack.best_replace (mkFix fix) cst_l t + Cst_stack.best_replace sigma (mkFix fix) cst_l t else t in recfun x (t',sk')) - [] refold Cst_stack.empty raw_answer sk + [] sigma refold Cst_stack.empty raw_answer sk let fix_recarg ((recindices,bodynum),_) stack = assert (0 <= bodynum && bodynum < Array.length recindices); @@ -789,7 +827,7 @@ let fix_recarg ((recindices,bodynum),_) stack = let debug_RAKAM = ref (false) let _ = Goptions.declare_bool_option { - Goptions.optsync = true; Goptions.optdepr = false; + Goptions.optdepr = false; Goptions.optname = "Print states of the Reductionops abstract machine"; Goptions.optkey = ["Debug";"RAKAM"]; @@ -797,30 +835,30 @@ let _ = Goptions.declare_bool_option { Goptions.optwrite = (fun a -> debug_RAKAM:=a); } -let equal_stacks (x, l) (y, l') = - let f_equal (x,lft1) (y,lft2) = Constr.equal (Vars.lift lft1 x) (Vars.lift lft2 y) in - let eq_fix (a,b) (c,d) = f_equal (Constr.mkFix a, b) (Constr.mkFix c, d) in - match Stack.equal f_equal eq_fix l l' with - | None -> false - | Some (lft1,lft2) -> f_equal (x, lft1) (y, lft2) +let equal_stacks sigma (x, l) (y, l') = + let f_equal x y = eq_constr sigma x y in + let eq_fix a b = f_equal (mkFix a) (mkFix b) in + Stack.equal f_equal eq_fix l l' && f_equal x y let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = let open Context.Named.Declaration in - let rec whrec cst_l (x, stack as s) = + let rec whrec cst_l (x, stack) = let () = if !debug_RAKAM then let open Pp in + let pr c = Termops.print_constr c in Feedback.msg_notice - (h 0 (str "<<" ++ Termops.print_constr x ++ + (h 0 (str "<<" ++ pr x ++ str "|" ++ cut () ++ Cst_stack.pr cst_l ++ - str "|" ++ cut () ++ Stack.pr Termops.print_constr stack ++ + str "|" ++ cut () ++ Stack.pr pr stack ++ str ">>")) in + let c0 = EConstr.kind sigma x in let fold () = let () = if !debug_RAKAM then let open Pp in Feedback.msg_notice (str "<><><><><>") in - (s,cst_l) + ((EConstr.of_kind c0, stack),cst_l) in - match kind_of_term x with + match c0 with | Rel n when CClosure.RedFlags.red_set flags CClosure.RedFlags.fDELTA -> (match lookup_rel n env with | LocalDef (_,body,_) -> whrec Cst_stack.empty (lift n body, stack) @@ -830,18 +868,20 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = | LocalDef (_,body,_) -> whrec (if refold then Cst_stack.add_cst (mkVar id) cst_l else cst_l) (body, stack) | _ -> fold ()) - | Evar ev -> - (match safe_evar_value sigma ev with - | Some body -> whrec cst_l (body, stack) - | None -> fold ()) + | Evar ev -> fold () | Meta ev -> (match safe_meta_value sigma ev with - | Some body -> whrec cst_l (body, stack) + | Some body -> whrec cst_l (EConstr.of_constr body, stack) | None -> fold ()) - | Const (c,u as const) when CClosure.RedFlags.red_set flags (CClosure.RedFlags.fCONST c) -> - (match constant_opt_value_in env const with + | Const (c,u as const) -> + reduction_effect_hook env sigma (EConstr.to_constr sigma x) + (lazy (EConstr.to_constr sigma (Stack.zip sigma (x,stack)))); + if CClosure.RedFlags.red_set flags (CClosure.RedFlags.fCONST c) then + let u' = EInstance.kind sigma u in + (match constant_opt_value_in env (c, u') with | None -> fold () | Some body -> + let body = EConstr.of_constr body in if not tactic_mode then whrec (if refold then Cst_stack.add_cst (mkConstU const) cst_l else cst_l) (body, stack) @@ -858,12 +898,12 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = let (tm',sk'),cst_l' = whrec (Cst_stack.add_cst (mkConstU const) cst_l) (body, app_sk) in - let rec is_case x = match kind_of_term x with + let rec is_case x = match EConstr.kind sigma x with | Lambda (_,_, x) | LetIn (_,_,_, x) | Cast (x, _,_) -> is_case x | App (hd, _) -> is_case hd | Case _ -> true | _ -> false in - if equal_stacks (x, app_sk) (tm', sk') + if equal_stacks sigma (x, app_sk) (tm', sk') || Stack.will_expose_iota sk' || is_case tm' then fold () @@ -877,8 +917,8 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = | None -> fold () | Some (bef,arg,s') -> whrec Cst_stack.empty - (arg,Stack.Cst(Stack.Cst_const const,curr,remains,bef,cst_l)::s') - ) + (arg,Stack.Cst(Stack.Cst_const (fst const, u'),curr,remains,bef,cst_l)::s') + ) else fold () | Proj (p, c) when CClosure.RedFlags.red_projection flags p -> (let pb = lookup_projection p env in let kn = Projection.constant p in @@ -891,7 +931,7 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = | None -> let stack' = (c, Stack.Proj (npars, arg, p, cst_l) :: stack) in let stack'', csts = whrec Cst_stack.empty stack' in - if equal_stacks stack' stack'' then fold () + if equal_stacks sigma stack' stack'' then fold () else stack'', csts | Some (recargs, nargs, flags) -> if (List.mem `ReductionNeverUnfold flags @@ -921,7 +961,7 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = Stack.append_app [|c|] bef,cst_l)::s')) | LetIn (_,b,_,c) when CClosure.RedFlags.red_set flags CClosure.RedFlags.fZETA -> - apply_subst whrec [b] refold cst_l c stack + apply_subst (fun _ -> whrec) [b] sigma refold cst_l c stack | Cast (c,_,_) -> whrec cst_l (c, stack) | App (f,cl) -> whrec @@ -930,20 +970,20 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = | Lambda (na,t,c) -> (match Stack.decomp stack with | Some _ when CClosure.RedFlags.red_set flags CClosure.RedFlags.fBETA -> - apply_subst whrec [] refold cst_l x stack + apply_subst (fun _ -> whrec) [] sigma refold cst_l x stack | None when CClosure.RedFlags.red_set flags CClosure.RedFlags.fETA -> - let env' = push_rel (LocalAssum (na,t)) env in + let env' = push_rel (LocalAssum (na, t)) env in let whrec' = whd_state_gen ~refold ~tactic_mode flags env' sigma in - (match kind_of_term (Stack.zip ~refold (fst (whrec' (c, Stack.empty)))) with + (match EConstr.kind sigma (Stack.zip ~refold sigma (fst (whrec' (c, Stack.empty)))) with | App (f,cl) -> let napp = Array.length cl in if napp > 0 then let (x', l'),_ = whrec' (Array.last cl, Stack.empty) in - match kind_of_term x', l' with + match EConstr.kind sigma x', l' with | Rel 1, [] -> let lc = Array.sub cl 0 (napp-1) in - let u = if Int.equal napp 1 then f else appvect (f,lc) in - if noccurn 1 u then (pop u,Stack.empty),Cst_stack.empty else fold () + let u = if Int.equal napp 1 then f else mkApp (f,lc) in + if noccurn sigma 1 u then (pop u,Stack.empty),Cst_stack.empty else fold () | _ -> fold () else fold () | _ -> fold ()) @@ -968,11 +1008,11 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = |args, (Stack.Proj (n,m,p,_)::s') when use_match -> whrec Cst_stack.empty (Stack.nth args (n+m), s') |args, (Stack.Fix (f,s',cst_l)::s'') when use_fix -> - let x' = Stack.zip(x,args) in + let x' = Stack.zip sigma (x, args) in let out_sk = s' @ (Stack.append_app [|x'|] s'') in - reduce_and_refold_fix whrec env refold cst_l f out_sk + reduce_and_refold_fix whrec env sigma refold cst_l f out_sk |args, (Stack.Cst (const,curr,remains,s',cst_l) :: s'') -> - let x' = Stack.zip(x,args) in + let x' = Stack.zip sigma (x, args) in begin match remains with | [] -> (match const with @@ -980,6 +1020,8 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = (match constant_opt_value_in env const with | None -> fold () | Some body -> + let const = (fst const, EInstance.make (snd const)) in + let body = EConstr.of_constr body in whrec (if refold then Cst_stack.add_cst (mkConstU const) cst_l else cst_l) (body, s' @ (Stack.append_app [|x'|] s''))) | Stack.Cst_proj p -> @@ -998,7 +1040,7 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = (arg, Stack.Cst (const,next,remains',s' @ (Stack.append_app [|x'|] bef),cst_l) :: s''') end - |_, (Stack.App _|Stack.Update _|Stack.Shift _)::_ -> assert false + |_, (Stack.App _)::_ -> assert false |_, _ -> fold () else fold () @@ -1006,40 +1048,42 @@ let rec whd_state_gen ?csts ~refold ~tactic_mode flags env sigma = if CClosure.RedFlags.red_set flags CClosure.RedFlags.fCOFIX then match Stack.strip_app stack with |args, ((Stack.Case _ |Stack.Proj _)::s') -> - reduce_and_refold_cofix whrec env refold cst_l cofix stack + reduce_and_refold_cofix whrec env sigma refold cst_l cofix stack |_ -> fold () else fold () - | Rel _ | Var _ | Const _ | LetIn _ | Proj _ -> fold () + | Rel _ | Var _ | LetIn _ | Proj _ -> fold () | Sort _ | Ind _ | Prod _ -> fold () in fun xs -> let (s,cst_l as res) = whrec (Option.default Cst_stack.empty csts) xs in - if tactic_mode then (Stack.best_state s cst_l,Cst_stack.empty) else res + if tactic_mode then (Stack.best_state sigma s cst_l,Cst_stack.empty) else res (** reduction machine without global env and refold machinery *) let local_whd_state_gen flags sigma = - let rec whrec (x, stack as s) = - match kind_of_term x with + let rec whrec (x, stack) = + let c0 = EConstr.kind sigma x in + let s = (EConstr.of_kind c0, stack) in + match c0 with | LetIn (_,b,_,c) when CClosure.RedFlags.red_set flags CClosure.RedFlags.fZETA -> - stacklam whrec [b] c stack + stacklam whrec [b] sigma c stack | Cast (c,_,_) -> whrec (c, stack) | App (f,cl) -> whrec (f, Stack.append_app cl stack) | Lambda (_,_,c) -> (match Stack.decomp stack with | Some (a,m) when CClosure.RedFlags.red_set flags CClosure.RedFlags.fBETA -> - stacklam whrec [a] c m + stacklam whrec [a] sigma c m | None when CClosure.RedFlags.red_set flags CClosure.RedFlags.fETA -> - (match kind_of_term (Stack.zip (whrec (c, Stack.empty))) with + (match EConstr.kind sigma (Stack.zip sigma (whrec (c, Stack.empty))) with | App (f,cl) -> let napp = Array.length cl in if napp > 0 then let x', l' = whrec (Array.last cl, Stack.empty) in - match kind_of_term x', l' with + match EConstr.kind sigma x', l' with | Rel 1, [] -> let lc = Array.sub cl 0 (napp-1) in - let u = if Int.equal napp 1 then f else appvect (f,lc) in - if noccurn 1 u then (pop u,Stack.empty) else s + let u = if Int.equal napp 1 then f else mkApp (f,lc) in + if noccurn sigma 1 u then (pop u,Stack.empty) else s | _ -> s else s | _ -> s) @@ -1059,14 +1103,10 @@ let local_whd_state_gen flags sigma = |None -> s |Some (bef,arg,s') -> whrec (arg, Stack.Fix(f,bef,Cst_stack.empty)::s')) - | Evar ev -> - (match safe_evar_value sigma ev with - Some c -> whrec (c,stack) - | None -> s) - + | Evar ev -> s | Meta ev -> (match safe_meta_value sigma ev with - Some c -> whrec (c,stack) + Some c -> whrec (EConstr.of_constr c,stack) | None -> s) | Construct ((ind,c),u) -> @@ -1079,9 +1119,9 @@ let local_whd_state_gen flags sigma = |args, (Stack.Proj (n,m,p,_) :: s') when use_match -> whrec (Stack.nth args (n+m), s') |args, (Stack.Fix (f,s',cst)::s'') when use_fix -> - let x' = Stack.zip(x,args) in - whrec (contract_fix f, s' @ (Stack.append_app [|x'|] s'')) - |_, (Stack.App _|Stack.Update _|Stack.Shift _|Stack.Cst _)::_ -> assert false + let x' = Stack.zip sigma (x,args) in + whrec (contract_fix sigma f, s' @ (Stack.append_app [|x'|] s'')) + |_, (Stack.App _|Stack.Cst _)::_ -> assert false |_, _ -> s else s @@ -1089,32 +1129,35 @@ let local_whd_state_gen flags sigma = if CClosure.RedFlags.red_set flags CClosure.RedFlags.fCOFIX then match Stack.strip_app stack with |args, ((Stack.Case _ | Stack.Proj _)::s') -> - whrec (contract_cofix cofix, stack) + whrec (contract_cofix sigma cofix, stack) |_ -> s else s - | x -> s + | Rel _ | Var _ | Sort _ | Prod _ | LetIn _ | Const _ | Ind _ | Proj _ -> s + in whrec let raw_whd_state_gen flags env = - let f sigma s = fst (whd_state_gen (get_refolding_in_reduction ()) false flags env sigma s) in + let f sigma s = fst (whd_state_gen ~refold:false + ~tactic_mode:false + flags env sigma s) in f let stack_red_of_state_red f = - let f sigma x = decompose_app (Stack.zip (f sigma (x, Stack.empty))) in + let f sigma x = EConstr.decompose_app sigma (Stack.zip sigma (f sigma (x, Stack.empty))) in f (* Drops the Cst_stack *) let iterate_whd_gen refold flags env sigma s = let rec aux t = - let (hd,sk),_ = whd_state_gen refold false flags env sigma (t,Stack.empty) in + let (hd,sk),_ = whd_state_gen ~refold ~tactic_mode:false flags env sigma (t,Stack.empty) in let whd_sk = Stack.map aux sk in - Stack.zip ~refold (hd,whd_sk) + Stack.zip sigma ~refold (hd,whd_sk) in aux s let red_of_state_red f sigma x = - Stack.zip (f sigma (x,Stack.empty)) + Stack.zip sigma (f sigma (x,Stack.empty)) (* 0. No Reduction Functions *) @@ -1169,7 +1212,7 @@ let whd_allnolet env = (* 4. Ad-hoc eta reduction, does not subsitute evars *) -let shrink_eta c = Stack.zip (local_whd_state_gen eta Evd.empty (c,Stack.empty)) +let shrink_eta c = Stack.zip Evd.empty (local_whd_state_gen eta Evd.empty (c,Stack.empty)) (* 5. Zeta Reduction Functions *) @@ -1191,14 +1234,24 @@ let nf_evar = Evarutil.nf_evar let clos_norm_flags flgs env sigma t = try let evars ev = safe_evar_value sigma ev in - CClosure.norm_val + EConstr.of_constr (CClosure.norm_val + (CClosure.create_clos_infos ~evars flgs env) + (CClosure.create_tab ()) + (CClosure.inject (EConstr.Unsafe.to_constr t))) + with e when is_anomaly e -> user_err Pp.(str "Tried to normalize ill-typed term") + +let clos_whd_flags flgs env sigma t = + try + let evars ev = safe_evar_value sigma ev in + EConstr.of_constr (CClosure.whd_val (CClosure.create_clos_infos ~evars flgs env) - (CClosure.inject t) - with e when is_anomaly e -> error "Tried to normalize ill-typed term" + (CClosure.create_tab ()) + (CClosure.inject (EConstr.Unsafe.to_constr t))) + with e when is_anomaly e -> user_err Pp.(str "Tried to normalize ill-typed term") -let nf_beta = clos_norm_flags CClosure.beta (Global.env ()) -let nf_betaiota = clos_norm_flags CClosure.betaiota (Global.env ()) -let nf_betaiotazeta = clos_norm_flags CClosure.betaiotazeta (Global.env ()) +let nf_beta = clos_norm_flags CClosure.beta +let nf_betaiota = clos_norm_flags CClosure.betaiota +let nf_betaiotazeta = clos_norm_flags CClosure.betaiotazeta let nf_all env sigma = clos_norm_flags CClosure.all env sigma @@ -1207,11 +1260,11 @@ let nf_all env sigma = (* Conversion *) (********************************************************************) (* -let fkey = Profile.declare_profile "fhnf";; -let fhnf info v = Profile.profile2 fkey fhnf info v;; +let fkey = CProfile.declare_profile "fhnf";; +let fhnf info v = CProfile.profile2 fkey fhnf info v;; -let fakey = Profile.declare_profile "fhnf_apply";; -let fhnf_apply info k h a = Profile.profile4 fakey fhnf_apply info k h a;; +let fakey = CProfile.declare_profile "fhnf_apply";; +let fhnf_apply info k h a = CProfile.profile4 fakey fhnf_apply info k h a;; *) let is_transparent e k = @@ -1221,7 +1274,7 @@ let is_transparent e k = (* Conversion utility functions *) -type conversion_test = constraints -> constraints +type conversion_test = Constraint.t -> Constraint.t let pb_is_equal pb = pb == Reduction.CONV @@ -1229,11 +1282,21 @@ let pb_equal = function | Reduction.CUMUL -> Reduction.CONV | Reduction.CONV -> Reduction.CONV -let report_anomaly _ = - let e = UserError ("", Pp.str "Conversion test raised an anomaly") in +let report_anomaly e = + let msg = Pp.(str "Conversion test raised an anomaly:" ++ + spc () ++ CErrors.print e) in + let e = UserError (None,msg) in let e = CErrors.push e in iraise e +let f_conv ?l2r ?reds env ?evars x y = + let inj = EConstr.Unsafe.to_constr in + Reduction.conv ?l2r ?reds env ?evars (inj x) (inj y) + +let f_conv_leq ?l2r ?reds env ?evars x y = + let inj = EConstr.Unsafe.to_constr in + Reduction.conv_leq ?l2r ?reds env ?evars (inj x) (inj y) + let test_trans_conversion (f: constr Reduction.extended_conversion_function) reds env sigma x y = try let evars ev = safe_evar_value sigma ev in @@ -1242,16 +1305,16 @@ let test_trans_conversion (f: constr Reduction.extended_conversion_function) red with Reduction.NotConvertible -> false | e when is_anomaly e -> report_anomaly e -let is_conv ?(reds=full_transparent_state) env sigma = test_trans_conversion Reduction.conv reds env sigma -let is_conv_leq ?(reds=full_transparent_state) env sigma = test_trans_conversion Reduction.conv_leq reds env sigma +let is_conv ?(reds=full_transparent_state) env sigma = test_trans_conversion f_conv reds env sigma +let is_conv_leq ?(reds=full_transparent_state) env sigma = test_trans_conversion f_conv_leq reds env sigma let is_fconv ?(reds=full_transparent_state) = function | Reduction.CONV -> is_conv ~reds | Reduction.CUMUL -> is_conv_leq ~reds let check_conv ?(pb=Reduction.CUMUL) ?(ts=full_transparent_state) env sigma x y = let f = match pb with - | Reduction.CONV -> Reduction.conv - | Reduction.CUMUL -> Reduction.conv_leq + | Reduction.CONV -> f_conv + | Reduction.CUMUL -> f_conv_leq in try f ~reds:ts env ~evars:(safe_evar_value sigma, Evd.universes sigma) x y; true with Reduction.NotConvertible -> false @@ -1269,23 +1332,34 @@ let sigma_compare_instances ~flex i0 i1 sigma = | Univ.UniverseInconsistency _ -> raise Reduction.NotConvertible +let sigma_check_inductive_instances cv_pb variance u1 u2 sigma = + match Evarutil.compare_cumulative_instances cv_pb variance u1 u2 sigma with + | Inl sigma -> sigma + | Inr _ -> + raise Reduction.NotConvertible + let sigma_univ_state = - { Reduction.compare = sigma_compare_sorts; - Reduction.compare_instances = sigma_compare_instances } + let open Reduction in + { compare_sorts = sigma_compare_sorts; + compare_instances = sigma_compare_instances; + compare_cumul_instances = sigma_check_inductive_instances; } let infer_conv_gen conv_fun ?(catch_incon=true) ?(pb=Reduction.CUMUL) ?(ts=full_transparent_state) env sigma x y = + (** FIXME *) try - let fold cstr sigma = - try Some (Evd.add_universe_constraints sigma cstr) - with Univ.UniverseInconsistency _ | Evd.UniversesDiffer -> None - in let b, sigma = let ans = if pb == Reduction.CUMUL then - Universes.leq_constr_univs_infer (Evd.universes sigma) fold x y sigma + EConstr.leq_constr_universes env sigma x y else - Universes.eq_constr_univs_infer (Evd.universes sigma) fold x y sigma + EConstr.eq_constr_universes env sigma x y + in + let ans = match ans with + | None -> None + | Some cstr -> + try Some (Evd.add_universe_constraints sigma cstr) + with Univ.UniverseInconsistency _ | Evd.UniversesDiffer -> None in match ans with | None -> false, sigma @@ -1293,6 +1367,8 @@ let infer_conv_gen conv_fun ?(catch_incon=true) ?(pb=Reduction.CUMUL) in if b then sigma, true else + let x = EConstr.Unsafe.to_constr x in + let y = EConstr.Unsafe.to_constr y in let sigma' = conv_fun pb ~l2r:false sigma ts env (sigma, sigma_univ_state) x y in @@ -1315,37 +1391,37 @@ let vm_infer_conv ?(pb=Reduction.CUMUL) env t1 t2 = (* Special-Purpose Reduction *) (********************************************************************) -let whd_meta sigma c = match kind_of_term c with - | Meta p -> (try meta_value sigma p with Not_found -> c) +let whd_meta sigma c = match EConstr.kind sigma c with + | Meta p -> (try EConstr.of_constr (meta_value sigma p) with Not_found -> c) | _ -> c let default_plain_instance_ident = Id.of_string "H" (* Try to replace all metas. Does not replace metas in the metas' values * Differs from (strong whd_meta). *) -let plain_instance s c = - let rec irec n u = match kind_of_term u with +let plain_instance sigma s c = + let rec irec n u = match EConstr.kind sigma u with | Meta p -> (try lift n (Metamap.find p s) with Not_found -> u) - | App (f,l) when isCast f -> - let (f,_,t) = destCast f in + | App (f,l) when isCast sigma f -> + let (f,_,t) = destCast sigma f in let l' = CArray.Fun1.smartmap irec n l in - (match kind_of_term f with + (match EConstr.kind sigma f with | Meta p -> (* Don't flatten application nodes: this is used to extract a proof-term from a proof-tree and we want to keep the structure of the proof-tree *) (try let g = Metamap.find p s in - match kind_of_term g with + match EConstr.kind sigma g with | App _ -> let l' = CArray.Fun1.smartmap lift 1 l' in mkLetIn (Name default_plain_instance_ident,g,t,mkApp(mkRel 1, l')) | _ -> mkApp (g,l') with Not_found -> mkApp (f,l')) | _ -> mkApp (irec n f,l')) - | Cast (m,_,_) when isMeta m -> - (try lift n (Metamap.find (destMeta m) s) with Not_found -> u) + | Cast (m,_,_) when isMeta sigma m -> + (try lift n (Metamap.find (destMeta sigma m) s) with Not_found -> u) | _ -> - map_constr_with_binders succ irec n u + map_with_binders sigma succ irec n u in if Metamap.is_empty s then c else irec 0 c @@ -1386,7 +1462,7 @@ let plain_instance s c = let instance sigma s c = (* if s = [] then c else *) - local_strong whd_betaiota sigma (plain_instance s c) + local_strong whd_betaiota sigma (plain_instance sigma s c) (* pseudo-reduction rule: * [hnf_prod_app env s (Prod(_,B)) N --> B[N] @@ -1395,34 +1471,33 @@ let instance sigma s c = * error message. *) let hnf_prod_app env sigma t n = - match kind_of_term (whd_all env sigma t) with + match EConstr.kind sigma (whd_all env sigma t) with | Prod (_,_,b) -> subst1 n b - | _ -> anomaly ~label:"hnf_prod_app" (Pp.str "Need a product") + | _ -> anomaly ~label:"hnf_prod_app" (Pp.str "Need a product.") let hnf_prod_appvect env sigma t nl = - Array.fold_left (hnf_prod_app env sigma) t nl + Array.fold_left (fun acc t -> hnf_prod_app env sigma acc t) t nl let hnf_prod_applist env sigma t nl = - List.fold_left (hnf_prod_app env sigma) t nl + List.fold_left (fun acc t -> hnf_prod_app env sigma acc t) t nl let hnf_lam_app env sigma t n = - match kind_of_term (whd_all env sigma t) with + match EConstr.kind sigma (whd_all env sigma t) with | Lambda (_,_,b) -> subst1 n b - | _ -> anomaly ~label:"hnf_lam_app" (Pp.str "Need an abstraction") + | _ -> anomaly ~label:"hnf_lam_app" (Pp.str "Need an abstraction.") let hnf_lam_appvect env sigma t nl = - Array.fold_left (hnf_lam_app env sigma) t nl + Array.fold_left (fun acc t -> hnf_lam_app env sigma acc t) t nl let hnf_lam_applist env sigma t nl = - List.fold_left (hnf_lam_app env sigma) t nl + List.fold_left (fun acc t -> hnf_lam_app env sigma acc t) t nl let splay_prod env sigma = let rec decrec env m c = let t = whd_all env sigma c in - match kind_of_term t with + match EConstr.kind sigma t with | Prod (n,a,c0) -> - decrec (push_rel (LocalAssum (n,a)) env) - ((n,a)::m) c0 + decrec (push_rel (LocalAssum (n,a)) env) ((n,a)::m) c0 | _ -> m,t in decrec env [] @@ -1430,10 +1505,9 @@ let splay_prod env sigma = let splay_lam env sigma = let rec decrec env m c = let t = whd_all env sigma c in - match kind_of_term t with + match EConstr.kind sigma t with | Lambda (n,a,c0) -> - decrec (push_rel (LocalAssum (n,a)) env) - ((n,a)::m) c0 + decrec (push_rel (LocalAssum (n,a)) env) ((n,a)::m) c0 | _ -> m,t in decrec env [] @@ -1441,7 +1515,7 @@ let splay_lam env sigma = let splay_prod_assum env sigma = let rec prodec_rec env l c = let t = whd_allnolet env sigma c in - match kind_of_term t with + match EConstr.kind sigma t with | Prod (x,t,c) -> prodec_rec (push_rel (LocalAssum (x,t)) env) (Context.Rel.add (LocalAssum (x,t)) l) c @@ -1451,14 +1525,14 @@ let splay_prod_assum env sigma = | Cast (c,_,_) -> prodec_rec env l c | _ -> let t' = whd_all env sigma t in - if Term.eq_constr t t' then l,t + if EConstr.eq_constr sigma t t' then l,t else prodec_rec env l t' in prodec_rec env Context.Rel.empty let splay_arity env sigma c = let l, c = splay_prod env sigma c in - match kind_of_term c with + match EConstr.kind sigma c with | Sort s -> l,s | _ -> invalid_arg "splay_arity" @@ -1466,7 +1540,7 @@ let sort_of_arity env sigma c = snd (splay_arity env sigma c) let splay_prod_n env sigma n = let rec decrec env m ln c = if Int.equal m 0 then (ln,c) else - match kind_of_term (whd_all env sigma c) with + match EConstr.kind sigma (whd_all env sigma c) with | Prod (n,a,c0) -> decrec (push_rel (LocalAssum (n,a)) env) (m-1) (Context.Rel.add (LocalAssum (n,a)) ln) c0 @@ -1476,7 +1550,7 @@ let splay_prod_n env sigma n = let splay_lam_n env sigma n = let rec decrec env m ln c = if Int.equal m 0 then (ln,c) else - match kind_of_term (whd_all env sigma c) with + match EConstr.kind sigma (whd_all env sigma c) with | Lambda (n,a,c0) -> decrec (push_rel (LocalAssum (n,a)) env) (m-1) (Context.Rel.add (LocalAssum (n,a)) ln) c0 @@ -1485,7 +1559,7 @@ let splay_lam_n env sigma n = decrec env n Context.Rel.empty let is_sort env sigma t = - match kind_of_term (whd_all env sigma t) with + match EConstr.kind sigma (whd_all env sigma t) with | Sort s -> true | _ -> false @@ -1493,7 +1567,7 @@ let is_sort env sigma t = of case/fix (heuristic used by evar_conv) *) let whd_betaiota_deltazeta_for_iota_state ts env sigma csts s = - let refold = get_refolding_in_reduction () in + let refold = false in let tactic_mode = false in let rec whrec csts s = let (t, stack as s),csts' = whd_state_gen ~csts ~refold ~tactic_mode CClosure.betaiota env sigma s in @@ -1501,24 +1575,24 @@ let whd_betaiota_deltazeta_for_iota_state ts env sigma csts s = |args, (Stack.Case _ :: _ as stack') -> let (t_o,stack_o),csts_o = whd_state_gen ~csts:csts' ~refold ~tactic_mode (CClosure.RedFlags.red_add_transparent CClosure.all ts) env sigma (t,args) in - if reducible_mind_case t_o then whrec csts_o (t_o, stack_o@stack') else s,csts' + if reducible_mind_case sigma t_o then whrec csts_o (t_o, stack_o@stack') else s,csts' |args, (Stack.Fix _ :: _ as stack') -> let (t_o,stack_o),csts_o = whd_state_gen ~csts:csts' ~refold ~tactic_mode (CClosure.RedFlags.red_add_transparent CClosure.all ts) env sigma (t,args) in - if isConstruct t_o then whrec csts_o (t_o, stack_o@stack') else s,csts' + if isConstruct sigma t_o then whrec csts_o (t_o, stack_o@stack') else s,csts' |args, (Stack.Proj (n,m,p,_) :: stack'') -> let (t_o,stack_o),csts_o = whd_state_gen ~csts:csts' ~refold ~tactic_mode (CClosure.RedFlags.red_add_transparent CClosure.all ts) env sigma (t,args) in - if isConstruct t_o then + if isConstruct sigma t_o then whrec Cst_stack.empty (Stack.nth stack_o (n+m), stack'') else s,csts' - |_, ((Stack.App _| Stack.Shift _|Stack.Update _|Stack.Cst _) :: _|[]) -> s,csts' + |_, ((Stack.App _|Stack.Cst _) :: _|[]) -> s,csts' in whrec csts s let find_conclusion env sigma = let rec decrec env c = let t = whd_all env sigma c in - match kind_of_term t with + match EConstr.kind sigma t with | Prod (x,t,c0) -> decrec (push_rel (LocalAssum (x,t)) env) c0 | Lambda (x,t,c0) -> decrec (push_rel (LocalAssum (x,t)) env) c0 | t -> t @@ -1538,7 +1612,7 @@ let meta_value evd mv = match meta_opt_fvalue evd mv with | Some (b,_) -> let metas = Metamap.bind valrec b.freemetas in - instance evd metas b.rebus + instance evd metas (EConstr.of_constr b.rebus) | None -> mkMeta mv in valrec mv @@ -1550,7 +1624,10 @@ let meta_instance sigma b = let c_sigma = Metamap.bind (fun mv -> meta_value sigma mv) fm in instance sigma c_sigma b.rebus -let nf_meta sigma c = meta_instance sigma (mk_freelisted c) +let nf_meta sigma c = + let c = EConstr.Unsafe.to_constr c in + let cl = mk_freelisted c in + meta_instance sigma { cl with rebus = EConstr.of_constr cl.rebus } (* Instantiate metas that create beta/iota redexes *) @@ -1564,78 +1641,80 @@ let meta_reducible_instance evd b = in let metas = Metaset.fold fold fm Metamap.empty in let rec irec u = - let u = whd_betaiota Evd.empty u in - match kind_of_term u with - | Case (ci,p,c,bl) when isMeta (strip_outer_cast c) -> - let m = destMeta (strip_outer_cast c) in + let u = whd_betaiota Evd.empty u (** FIXME *) in + match EConstr.kind evd u with + | Case (ci,p,c,bl) when EConstr.isMeta evd (strip_outer_cast evd c) -> + let m = destMeta evd (strip_outer_cast evd c) in (match try let g, s = Metamap.find m metas in + let g = EConstr.of_constr g in let is_coerce = match s with CoerceToType -> true | _ -> false in - if isConstruct g || not is_coerce then Some g else None + if isConstruct evd g || not is_coerce then Some g else None with Not_found -> None with | Some g -> irec (mkCase (ci,p,g,bl)) | None -> mkCase (ci,irec p,c,Array.map irec bl)) - | App (f,l) when isMeta (strip_outer_cast f) -> - let m = destMeta (strip_outer_cast f) in + | App (f,l) when EConstr.isMeta evd (strip_outer_cast evd f) -> + let m = destMeta evd (strip_outer_cast evd f) in (match try let g, s = Metamap.find m metas in + let g = EConstr.of_constr g in let is_coerce = match s with CoerceToType -> true | _ -> false in - if isLambda g || not is_coerce then Some g else None + if isLambda evd g || not is_coerce then Some g else None with Not_found -> None with | Some g -> irec (mkApp (g,l)) | None -> mkApp (f,Array.map irec l)) | Meta m -> (try let g, s = Metamap.find m metas in + let g = EConstr.of_constr g in let is_coerce = match s with CoerceToType -> true | _ -> false in if not is_coerce then irec g else u with Not_found -> u) - | Proj (p,c) when isMeta c || isCast c && isMeta (pi1 (destCast c)) -> - let m = try destMeta c with _ -> destMeta (pi1 (destCast c)) in + | Proj (p,c) when isMeta evd c || isCast evd c && isMeta evd (pi1 (destCast evd c)) (* What if two nested casts? *) -> + let m = try destMeta evd c with _ -> destMeta evd (pi1 (destCast evd c)) (* idem *) in (match try let g, s = Metamap.find m metas in + let g = EConstr.of_constr g in let is_coerce = match s with CoerceToType -> true | _ -> false in - if isConstruct g || not is_coerce then Some g else None + if isConstruct evd g || not is_coerce then Some g else None with Not_found -> None with | Some g -> irec (mkProj (p,g)) | None -> mkProj (p,c)) - | _ -> Constr.map irec u + | _ -> EConstr.map evd irec u in if Metaset.is_empty fm then (* nf_betaiota? *) b.rebus else irec b.rebus -let head_unfold_under_prod ts env _ c = - let unfold (cst,u as cstu) = +let head_unfold_under_prod ts env sigma c = + let unfold (cst,u) = + let cstu = (cst, EInstance.kind sigma u) in if Cpred.mem cst (snd ts) then match constant_opt_value_in env cstu with - | Some c -> c - | None -> mkConstU cstu - else mkConstU cstu in + | Some c -> EConstr.of_constr c + | None -> mkConstU (cst, u) + else mkConstU (cst, u) in let rec aux c = - match kind_of_term c with + match EConstr.kind sigma c with | Prod (n,t,c) -> mkProd (n,aux t, aux c) | _ -> - let (h,l) = decompose_app c in - match kind_of_term h with - | Const cst -> beta_applist (unfold cst,l) + let (h,l) = decompose_app_vect sigma c in + match EConstr.kind sigma h with + | Const cst -> beta_app sigma (unfold cst, l) | _ -> c in aux c let betazetaevar_applist sigma n c l = let rec stacklam n env t stack = if Int.equal n 0 then applist (substl env t, stack) else - match kind_of_term t, stack with + match EConstr.kind sigma t, stack with | Lambda(_,_,c), arg::stacktl -> stacklam (n-1) (arg::env) c stacktl | LetIn(_,b,_,c), _ -> stacklam (n-1) (substl env b::env) c stack - | Evar ev, _ -> - (match safe_evar_value sigma ev with - | Some body -> stacklam n env body stack - | None -> applist (substl env t, stack)) - | _ -> anomaly (Pp.str "Not enough lambda/let's") in + | Evar _, _ -> applist (substl env t, stack) + | _ -> anomaly (Pp.str "Not enough lambda/let's.") in stacklam n [] c l -- cgit v1.2.3